We report the synthesis, characterization, and photophysical properties of a series of organic receptors and their corresponding ReI metal complexes as anion probes featuring diindole and indolecarbazole interacting sites incorporating highly chromophoric π-conjugated bisquinoxaline moieties BN-2, BN-4, and BN-5. These sensing molecules are capable of recognizing fluoride, cyanide and pyrophosphate over other anions in DMSO solution with different sensitivities. The probe-anion interactions can be easily visualized via naked-eye colorimetric or luminescent responses. By interacting with anion, the absorption and luminescence change obvious, this is causing by (ICT, intramolecular charge transfer). Coordination of probe BN-2 to a ReI center increases the intrinsic acidity of indolecarbazole N-H protons and results in an enhanced sensitivity to anions, so that nature of Lewis acidity of ReI metal exert on the indolecarbazole to enhance probe BN-4 is more sensitive than probes BN-2, and BN-5. Compared with probes BN-2 and BN-4, probe BN-2 has weaker acidic indolecarbazole N-H protons and therefore simply forms hydrogen-bonding complexes with fluoride, phosphate, cyanide and pyrophosphate. Due to the higher acidity of indolecarbazole in BN-4, at high concentration of anion, probe BN-4 forms a hydrogen-bound complex which anion followed by indolecarbazole N-H deprotonation with fluoride, pyrophosphate. The sensitivity of anion sensing of probe BN-5 is recating low, because of the non-planar conformation of diindole-based recognition motifs.